var Delaunay;

(function () {
    "use strict";

    var EPSILON = 1.0 / 1048576.0;

    function supertriangle(vertices) {
        var xmin = Number.POSITIVE_INFINITY,
            ymin = Number.POSITIVE_INFINITY,
            xmax = Number.NEGATIVE_INFINITY,
            ymax = Number.NEGATIVE_INFINITY,
            i, dx, dy, dmax, xmid, ymid;

        for (i = vertices.length; i--; ) {
            if (vertices[i][0] < xmin) xmin = vertices[i][0];
            if (vertices[i][0] > xmax) xmax = vertices[i][0];
            if (vertices[i][1] < ymin) ymin = vertices[i][1];
            if (vertices[i][1] > ymax) ymax = vertices[i][1];
        }

        dx = xmax - xmin;
        dy = ymax - ymin;
        dmax = Math.max(dx, dy);
        xmid = xmin + dx * 0.5;
        ymid = ymin + dy * 0.5;

        return [
            [xmid - 20 * dmax, ymid - dmax],
            [xmid, ymid + 20 * dmax],
            [xmid + 20 * dmax, ymid - dmax]
        ];
    }

    function circumcircle(vertices, i, j, k) {
        var x1 = vertices[i][0],
            y1 = vertices[i][1],
            x2 = vertices[j][0],
            y2 = vertices[j][1],
            x3 = vertices[k][0],
            y3 = vertices[k][1],
            fabsy1y2 = Math.abs(y1 - y2),
            fabsy2y3 = Math.abs(y2 - y3),
            xc, yc, m1, m2, mx1, mx2, my1, my2, dx, dy;

        /* Check for coincident points */
        if (fabsy1y2 < EPSILON && fabsy2y3 < EPSILON)
            throw new Error("Eek! Coincident points!");

        if (fabsy1y2 < EPSILON) {
            m2 = -((x3 - x2) / (y3 - y2));
            mx2 = (x2 + x3) / 2.0;
            my2 = (y2 + y3) / 2.0;
            xc = (x2 + x1) / 2.0;
            yc = m2 * (xc - mx2) + my2;
        }

        else if (fabsy2y3 < EPSILON) {
            m1 = -((x2 - x1) / (y2 - y1));
            mx1 = (x1 + x2) / 2.0;
            my1 = (y1 + y2) / 2.0;
            xc = (x3 + x2) / 2.0;
            yc = m1 * (xc - mx1) + my1;
        }

        else {
            m1 = -((x2 - x1) / (y2 - y1));
            m2 = -((x3 - x2) / (y3 - y2));
            mx1 = (x1 + x2) / 2.0;
            mx2 = (x2 + x3) / 2.0;
            my1 = (y1 + y2) / 2.0;
            my2 = (y2 + y3) / 2.0;
            xc = (m1 * mx1 - m2 * mx2 + my2 - my1) / (m1 - m2);
            yc = (fabsy1y2 > fabsy2y3) ?
                m1 * (xc - mx1) + my1 :
                m2 * (xc - mx2) + my2;
        }

        dx = x2 - xc;
        dy = y2 - yc;
        return { i: i, j: j, k: k, x: xc, y: yc, r: dx * dx + dy * dy };
    }

    function dedup(edges) {
        var i, j, a, b, m, n;

        for (j = edges.length; j; ) {
            b = edges[--j];
            a = edges[--j];

            for (i = j; i; ) {
                n = edges[--i];
                m = edges[--i];

                if ((a === m && b === n) || (a === n && b === m)) {
                    edges.splice(j, 2);
                    edges.splice(i, 2);
                    break;
                }
            }
        }
    }

    Delaunay = {
        triangulate: function (vertices, key) {
            var n = vertices.length,
                i, j, indices, st, open, closed, edges, dx, dy, a, b, c;

            /* Bail if there aren't enough vertices to form any triangles. */
            if (n < 3)
                return [];

            /* Slice out the actual vertices from the passed objects. (Duplicate the
            * array even if we don't, though, since we need to make a supertriangle
            * later on!) */
            vertices = vertices.slice(0);

            if (key)
                for (i = n; i--; )
                    vertices[i] = vertices[i][key];

            /* Make an array of indices into the vertex array, sorted by the
            * vertices' x-position. */
            indices = new Array(n);

            for (i = n; i--; )
                indices[i] = i;

            indices.sort(function (i, j) {
                return vertices[j][0] - vertices[i][0];
            });

            /* Next, find the vertices of the supertriangle (which contains all other
            * triangles), and append them onto the end of a (copy of) the vertex
            * array. */
            st = supertriangle(vertices);
            vertices.push(st[0], st[1], st[2]);

            /* Initialize the open list (containing the supertriangle and nothing
            * else) and the closed list (which is empty since we havn't processed
            * any triangles yet). */
            open = [circumcircle(vertices, n + 0, n + 1, n + 2)];
            closed = [];
            edges = [];

            /* Incrementally add each vertex to the mesh. */
            for (i = indices.length; i--; edges.length = 0) {
                c = indices[i];

                /* For each open triangle, check to see if the current point is
                * inside it's circumcircle. If it is, remove the triangle and add
                * it's edges to an edge list. */
                for (j = open.length; j--; ) {
                    /* If this point is to the right of this triangle's circumcircle,
                    * then this triangle should never get checked again. Remove it
                    * from the open list, add it to the closed list, and skip. */
                    dx = vertices[c][0] - open[j].x;
                    if (dx > 0.0 && dx * dx > open[j].r) {
                        closed.push(open[j]);
                        open.splice(j, 1);
                        continue;
                    }

                    /* If we're outside the circumcircle, skip this triangle. */
                    dy = vertices[c][1] - open[j].y;
                    if (dx * dx + dy * dy - open[j].r > EPSILON)
                        continue;

                    /* Remove the triangle and add it's edges to the edge list. */
                    edges.push(
                        open[j].i, open[j].j,
                        open[j].j, open[j].k,
                        open[j].k, open[j].i
                    );
                    open.splice(j, 1);
                }

                /* Remove any doubled edges. */
                dedup(edges);

                /* Add a new triangle for each edge. */
                for (j = edges.length; j; ) {
                    b = edges[--j];
                    a = edges[--j];
                    open.push(circumcircle(vertices, a, b, c));
                }
            }

            /* Copy any remaining open triangles to the closed list, and then
            * remove any triangles that share a vertex with the supertriangle,
            * building a list of triplets that represent triangles. */
            for (i = open.length; i--; )
                closed.push(open[i]);
            open.length = 0;

            for (i = closed.length; i--; )
                if (closed[i].i < n && closed[i].j < n && closed[i].k < n)
                    open.push(closed[i].i, closed[i].j, closed[i].k);

            /* Yay, we're done! */
            return open;
        },
        contains: function (tri, p) {
            /* Bounding box test first, for quick rejections. */
            if ((p[0] < tri[0][0] && p[0] < tri[1][0] && p[0] < tri[2][0]) ||
                (p[0] > tri[0][0] && p[0] > tri[1][0] && p[0] > tri[2][0]) ||
                (p[1] < tri[0][1] && p[1] < tri[1][1] && p[1] < tri[2][1]) ||
                (p[1] > tri[0][1] && p[1] > tri[1][1] && p[1] > tri[2][1]))
                return null;

            var a = tri[1][0] - tri[0][0],
                b = tri[2][0] - tri[0][0],
                c = tri[1][1] - tri[0][1],
                d = tri[2][1] - tri[0][1],
                i = a * d - b * c;

            /* Degenerate tri. */
            if (i === 0.0)
                return null;

            var u = (d * (p[0] - tri[0][0]) - b * (p[1] - tri[0][1])) / i,
                v = (a * (p[1] - tri[0][1]) - c * (p[0] - tri[0][0])) / i;

            /* If we're outside the tri, fail. */
            if (u < 0.0 || v < 0.0 || (u + v) > 1.0)
                return null;

            return [u, v];
        }
    };

    if (typeof module !== "undefined")
        module.exports = Delaunay;
})();